[1]
V.F. Loskutov et al., Diffusion carbide coatings, Tekhnika, Kiev, 1991. 168 p.
Google Scholar
[2]
I.M. Kovensky, V.V. Povetkin, Metallurgy of coatings, Sp. Intermet Engineering, Moscow, 1999. 295 p.
Google Scholar
[3]
F. Czerwinski, Heat Treatment - Conventional and Novel Applications, InTech, Janeza, Croatia, 2012. 408 p.
Google Scholar
[4]
G.V. Borisenok, L.A. Vasiliev, L.G. Voroshnin et al., Chemical - heat treatment of metals and alloys: a reference book, Metallurgy, Moscow, 1981. 424 p.
Google Scholar
[5]
Yu. M. Lakhtin, B.N. Arzamasov, Chemical - thermal treatment of metals, Metallurgy, Moscow, 1985. 256 p.
Google Scholar
[6]
Q.J. Wang, Y.W. Chung, Encyclopedia of tribology, Springer science + Business Media, New York, 2013. 4192 p.
Google Scholar
[7]
W. Lee, J. Duh, Evaluation of microstructures and mechanical properties of chromized steels with different carbon content, Surface and Coatings Technology 177-178 (2004) 525-531.
DOI: 10.1016/j.surfcoat.2003.08.031
Google Scholar
[8]
J. W. Lee, H. C. Wang, J. L. Li, C. C. Lin, Tribological properties evaluation of AISI 1095 steel chromized at different temperatures, Surface and coatings technology 188-189 (2004) 550-555.
DOI: 10.1016/j.surfcoat.2004.07.011
Google Scholar
[9]
N. Lin, F. Xie, H. Yang, W. Tian, H. Wang, B. Tang, Assessments on friction and wear behaviors of P110 steel and chromizing coating sliding against two counterparts under dry and wet conditions, 258 (2012) 4960-4970.
DOI: 10.1016/j.apsusc.2012.01.128
Google Scholar
[10]
C. Y. Bai, M. D. Ger, M. S. Wu, Corrosion behaviors and contact resistances of the low-carbon steel bipolar plate with a chromized coating containing carbides and nitrides, International journal of hydrogen energy 34 (2009) 6778-6789.
DOI: 10.1016/j.ijhydene.2009.05.103
Google Scholar
[11]
S.B. Lee, K.H. Cho, W. G. Lee, H. Jang, Improved corrosion resistance and interfacial contact resistance of 316L stainless steel for proton exchange membrane fuel cell bipolar plates by chromizing surface treatment, Journal of Power Sources 187 (2009) 318-323.
DOI: 10.1016/j.jpowsour.2008.11.064
Google Scholar
[12]
A. Agüero, V. González, M. Gutiérrez, R. Muelas, Oxidation under pure steam Cr based protective oxides and coatings, Surface and coatings technology 237 (2013) 30-38.
DOI: 10.1016/j.surfcoat.2013.09.016
Google Scholar
[13]
B.N. Arzamasov, V.N. Simonov, Circulation method of applying diffusion coatings, Metallurgy and heat treatment of metals 9 (2010) 3-7.
Google Scholar
[14]
G.H. Meier, C. Cheng, R.A. Perkins, W. Barker, Diffusion chromizing of ferrous alloys, Surface and Coatings Technology 39–40 (1989) 53-64.
DOI: 10.1016/0257-8972(89)90040-6
Google Scholar
[15]
R.F. Rolsten, Iodide metals and metal iodides, Metallurgy, Moscow, 1968. 524 p.
Google Scholar
[16]
S.P. Bogdanov, Obtaining coatings on powders by the method of iodine transport, Glass Physics and Chemistry 37(2) (2011) 229-237.
Google Scholar
[17]
R. Ripan, I Chetyanu, Inorganic chemistry. Chemistry of metals, Mir, Moscow, 1972. Vol. 2, 871 p.
Google Scholar
[18]
Xiaowei Yin I. et al 2005 Formation of titanium carbide on graphite via powder immersion reaction assisted coating, Materials Science and Engineering, A 396 (2005) 107-114.
DOI: 10.1016/j.msea.2005.01.011
Google Scholar
[19]
A.V. Khvan, B. Hallstedt, Ch. Broeckmann, A thermodynamic evaluation of the Fe – Cr – C system, CALPHAD: Computer Coupling of Phase Diagrams and Thermochemistry 46 (2014) 24-33.
DOI: 10.1016/j.calphad.2014.01.002
Google Scholar
[20]
S.P. Bogdanov, N.A. Khristiuk, Use of iodine transport for diffusion chromium plating of steel, Steel 1 (2017) 67-72.
Google Scholar